A method of reading data in a memory system including a non-volatile memory device, includes reading first data stored in a first block using a first read scheme capable of detecting/correcting an error in the first data, and upon determining an uncorrected error in the first data, setting the first block as a first temporary bad block and reading second data stored in the first temporary bad block using a second read scheme different from the first read scheme.
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9. A memory system comprising:
a non-volatile memory cell array including memory blocks that store data; and
a memory controller configured to control operation of the non-volatile memory cell array,
wherein the memory controller is configured to
read first data stored in a first block of the non-volatile memory cell array using a first read scheme, the first read scheme is capable of detecting/correcting an error in the first data, and upon determining an uncorrected error in the first data, setting the first block as a first temporary bad block,
read second data stored in the first temporary bad block using a second read scheme different from the first read scheme, the second read scheme is capable of detecting/correcting an error in the second data, and
read the first data stored in the first block using one of the first read scheme and the second read scheme according to the setting of the first block.
1. A method of reading data in a memory system including a non-volatile memory device, the method comprising:
reading first data stored in a first block of the non-volatile memory device using a first read scheme in response to a first read command, wherein the first read scheme is capable of detecting/correcting an error in the first data;
upon determining an uncorrected error in the first data, setting the first block as a first temporary bad block, and reading second data stored in the first temporary bad block using a second read scheme different from the first read scheme in response to a second read command, wherein the second read scheme is capable of detecting/correcting an error in the second data;
upon determining an uncorrected error in the second data, setting the first temporary bad block as a bad block; and
reading the first data stored in the first block using one of the first read scheme and the second read scheme according to the setting of the first block in response to the second read command.
2. The method of
3. The method of
programming write data to the first temporary bad block only if a given percentage of the total data storage capacity of the non-volatile memory device is exceeded.
4. The method of
reading the first data from the first temporary bad block only if a given percentage of total data storage capacity of the non-volatile memory device is exceeded.
5. The method of
correcting an error in the second data using the second read scheme, and programming the corrected second data to the first temporary bad block; and
reading the corrected second data from the first temporary bad block only if a given percentage of total data storage capacity of the non-volatile memory device is exceeded.
6. The method of
correcting an error in the second data using the second read scheme; and thereafter,
copying the corrected second data from the first block to a normal second block.
7. The method of
8. The method of
10. The memory system of
11. The memory system of
12. The memory system of
13. The memory system of
14. The memory system of
15. The memory system of
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This application claims the benefit of Korean Patent Application No. 10-2013-0072708 filed on Jun. 24, 2013, the subject matter of which is hereby incorporated by reference.
The inventive concept relates to memory devices, memory systems, and methods of reading data that provides improved read data reliability and data read speed.
As the quantities of data processed by contemporary memory devices and memory systems continues to increase, the speed with which data may be reliability “read” (i.e., retrieved from a stored location) has become an increasingly important performance parameter.
The inventive concept provides memory devices, memory systems, and methods of reading data characterized by improved operating reliability and speed.
In one embodiment, the inventive concept provides a method of reading data in a memory system including a non-volatile memory device, the method comprising; reading first data stored in a first block of the non-volatile memory device using a first read scheme in response to a first read command, wherein the first read scheme is capable of detecting/correcting an error in the first data, upon determining an uncorrected error in the first data, setting the first block as a first temporary bad block, and reading second data stored in the first temporary bad block using a second read scheme different from the first read scheme in response to a second read command, wherein the second read scheme is capable of detecting/correcting an error in the second data, upon determining an uncorrected error in the second data, setting the first temporary bad block as a bad block.
In another embodiment, the inventive concept provides a method of operating a memory system including a non-volatile memory device divided into memory blocks, the method comprising; using different read schemes to assign each memory block one of a range of read/write block designation levels, and thereafter, programming write data to each memory block in accordance with an assigned one of the read/write designation levels.
In another embodiment, the inventive concept provides a memory system comprising; a non-volatile memory cell array including memory blocks that store data, and a memory controller configured to control operation of the non-volatile memory cell array. The memory controller is configured to read first data stored in a first block of the non-volatile memory device using a first read scheme the first read scheme being capable of detecting/correcting an error in the first data, and upon determining an uncorrected error in the first data, setting the first block as a first temporary bad block, and is further configured to read second data stored in the first temporary bad block using a second read scheme different from the first read scheme, the second read scheme being capable of detecting/correcting an error in the second data.
Exemplary embodiments of the inventive concept will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings in which:
Hereinafter, embodiments of the inventive concept will be described with reference to the accompanying drawings. The inventive concept may, however, be embodied in many different forms and should not be construed as being limited to the illustrated embodiments. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the inventive concept to those of ordinary skill in the art. Throughout the written description and drawings, like reference numbers and label are used to denote like or similar elements.
The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the inventive concept. As used herein, the singular forms “a”, “an”, and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be understood that terms such as “comprise”, “include”, and “have”, when used herein, specify the presence of stated features, integers, steps, operations, elements, components, or combinations thereof, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.
Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the inventive concept belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.
Referring to
Thus, if the first attempt at reading the read data results in errant data, then a second attempt is made to read the read data stored in the first temporary bad block using a second read scheme different from the first read scheme. (S130). Thus, the second read attempt is made in response to a second read command that may (but need not be) be different from the first read command. Here again, as part of the second reading attempt, the second read scheme includes one or more processes that seek to detect/correct any data error(s) included in the read data. If at least one error in the read data cannot be corrected using the second read scheme (S135=Y), then the first temporary bad block is set (re-set, or further logically designated) as a “bad block” (S140).
In contrast, if the first read scheme (S115=N) or the second read scheme (S135=N) is successful in reading the read data stored in the first block or the first block designated as a first temporary bad block, then the read data may be provided to a circuit external to the non-volatile memory device as output data (S150).
Thus, referring to
In certain embodiments of the inventive concept, the non-volatile memory device of
The non-volatile memory device of
The memory controller of
For example, the read unit 110 may be used to generate the first read command [e.g., RCMD(V1, PAG1)] identifying the read data stored in a first page PAG1 of the first block BLK1 of the memory cell array 120. The first read command may further identify a hard read voltage (V1) that is used to make a “hard decision” according to the first read scheme (S110). That is, the memory controller will receive read data (R_DATA1) in response to the first read command, and then the memory controller will determine whether at least one data error is present in the read data in accordance with the hard-decision results provided as a result of executing the read operation using the first read scheme (S110).
However, when one or more uncorrected error(s) is detected in the read data (S115=Y), the read unit 110 of the memory controller may be used to generate a control command [e.g., MRK(BLK1, LEV1)] that sets the first block as a first temporary bad block (Bad Block_lev1) (S120). Further, when one or more uncorrected error(s) is detected in the read data (S115=Y), the read unit 110 of the memory controller may be used to generate a second read command (S117) [e.g., RCMD(V21, V22, PAG1)] again identifying read data stored at the first page PAG1 of the first block, but now also identifying one or more soft read voltages V21 and V22 that may be used to read to make a “soft decision” according to the second read scheme.
As a result, the memory controller will receive read data (e.g., R_DATA21, R_DATA22) in response to the second read command. If the execution of either the first or second read schemes results in acceptable read data (i.e., read data having none, or having an acceptable number of errors), then the read data may be provided as output read data (R_OUT) by the memory controller Mctrl.
In certain embodiments of the inventive concept, the memory controller Mctrl may perform error check (detect) and correction by using low density parity check (LDPC) routine. This possible approach will be described in some additional detail with reference to
Therefore, according to the following, when one or more uncorrected error(s) are present in read data (R_DATA1) obtained from the first block (BLK1) using the first read scheme (hereafter, “first read data”) in response to a first read (or hard decision) command, the non-volatile memory system 100 of
In effect, certain embodiments of the inventive concept may include a non-volatile memory system that performs a type of bad block levelling according to whether identified read data has been successfully read using the first read scheme or the second read scheme. In this context the term successful will be interrupted according to the error detect/correct capabilities of a particular read scheme. For example, when read data stored in the first block is not error-corrected while being read according the first read scheme, but is error-corrected while being read according to the second read scheme, the first block will be set as the first temporary bad block. However, when read data included in the first block is not error-corrected while being read according to the first and second read schemes, the first block will set as a bad block.
In view of these different designations, subsequently received read commands directed to a read data stored in a good block, verses a first temporary bad block, verses a bad block may be differently managed and processed, thereby making it possible to improve the overall operating speed of the memory device and/or constituent memory system.
Those skilled in the art will recognize that the use of two (2) read schemes is merely an example. Any reasonable number of data reading schemes having different error detect/correct capabilities may be similarly used in various embodiments of the inventive concept. As a result, memory blocks in a memory cell array may have one of a number of different “read/write block designation levels” ranging from a good block storing fully acceptable data, through a number (N) of different read impairment levels (e.g., first temporary, second temporary . . . Nth temporary) each storing read data of particular quality, down to bad blocks storing read data deemed un-correctable or fully unacceptable.
Further, the read block designations levels may be used during subsequent program operations to properly assigned write data being written to the memory cell array according to block quality. For example, incoming write data may not be written to (but may be read from) a block designated as a first temporary bad block, while incoming write data may be written to a block designated a second temporary bad block. Alternately, when incoming write data must be written to a memory device having 90% of its data storage capacity full, then write data may be written to designated first temporary bad block(s), wherein only when the memory device has 95% of its data storage capacity full may incoming write data be written to blocks designated as second temporary bad block(s). Consistent with the foregoing, write data is never written to, or read from a designated bad block.
Referring to
Next, it is assumed that first read data (R_DATA1) is retrieved from the first page PAG1 using the first read scheme and the hard read voltage V1. However, it is further assumed that the first read data is obtained as 1101000 (R_Data1[0˜6]). Upon receiving the first read data, the memory controller of
Because there is an error in the first read data (R_DATA1), the read unit 110 of the memory controller may be used to generate the second read command [e.g., RCMD(V21, V22, PAG1)] directed to the first page (PAG1) and indicating the use of soft read voltages V21 and V22. It is now assumed that second/first read data (R_DATA21) obtained using the first soft read voltage V21 is 1101000(R_Data21[0˜6]) and second/second read data (R_DATA22) obtained using the second soft read voltage V22 is 1101010(R_Data22[0˜6]). In the memory controller of
One possible soft decision scheme that may be used in certain embodiments of the inventive concept will be described in some additional detail with reference to
Referring to
Referring to
According to an embodiment of the inventive concept, the non-volatile memory device MEM may perform an erase operation in units of blocks, and perform a program operation in units of pages corresponding to word lines WL0 to WLe-1. The non-volatile memory device MEM may include a plurality of memory cell arrays that have the same structure and perform the same operation as the above-described memory cell array 120.
Each memory cell MCEL of the memory cell arrays included in the embodiments of
In the flash memory of
One bit, two bits or three or more bits of data may be set in a predetermined range of the threshold voltage Vth of the memory cell MCEL. Accordingly, one page or two or more pages may be set in each word line of
Referring to
Also, the non-volatile memory system 100 according to an embodiment of the inventive concept may include a non-volatile memory device MEM in which two or more bits of data is set in each threshold voltage range, that is, each threshold voltage distribution, as illustrated in
A NAND flash memory in which 3-bit data is programmed in a memory cell may be referred to as a triple-level cell (TLC) NAND flash memory. However, for the convenience of description, hereinafter, NAND flash memories in which two or more bits of data is programmed in a memory cell will be collectively referred to as an MLC NAND flash memory. In the MLC NAND flash memory, a hard read voltage may be set as three or more voltage levels in order to identify four or more threshold voltage distributions.
The non-volatile memory system 100 according to an embodiment of the inventive concept may include an SLC NAND flash memory or an MLC non-volatile memory device MEM, as described above. However, embodiments of the inventive concept are not limited thereto. The non-volatile memory system 100 according to an embodiment of the inventive concept may include both an SLC NAND flash memory and an MLC NAND flash memory. Also, the non-volatile memory device MEM according to an embodiment of the inventive may program data in some of the blocks BLK0 to BLKa-1 of
In the above-described flash memory according to an embodiment of the inventive concept, various performance degradation may occur due to its inherent structural limitation and peripheral environments. For example, as for the flash memory according to an embodiment of the inventive concept, a threshold voltage distribution set as illustrated in
Referring to
This error may be detected and/or corrected by an error check and correction (ECC) engine. For example, the ECC engine may generate parity data by encoding data to be written, and may detect and correct an error by decoding read data and parity data included therein.
Referring to
The hard read voltage HRV may have the same voltage level as the hard decision voltage that is used to identify the first threshold voltage distribution S1 and the second threshold voltage distribution S2. As described above, in the MLC flash memory having four or more threshold voltage distributions, the hard decision voltage may have a plurality of voltage levels. In this case, the hard read voltage HRV may have a voltage level for identification of the first threshold voltage distribution S1 and the second threshold voltage distribution S2, among the plurality of voltage levels. Data identified by the hard read voltage HRV may be referred to as hard data HD.
Next, the soft decision operation may sense soft data SD by sequentially applying a first soft read voltage SRV1a and a second soft read voltage SRV1b, which are paired and respectively have differences of a first voltage value ΔV1 and a second voltage value ΔV2 from the hard read voltage HRV, to the first page PGA1. The memory cell having a threshold voltage lower than the first soft read voltage SRV1a may be identified as “1”, and the memory cell having a threshold voltage higher than the first soft read voltage SRV1a and lower than the second soft read voltage SRV1b may be identified as “0”. The memory cell having a threshold voltage higher than the second soft read voltage SRV1b may be identified as “1”. Soft data SDTA may be generated by exclusively-ORing a bit value due to the on-off of the memory cell according to the first soft read voltage SRV1a and an inverse value of a bit value due to the on-off of the memory cell according to the second soft read voltage SRV1b.
In the example of
The non-volatile memory system 100 may set data (bit), which is read from the memory cell having a threshold voltage included in the period {circle around (1)} in which the reliability data RDTA is identified as “11”, as strong 1 (which represents that there is a high probability that a relevant data (bit) value will be identified as “1” and will be “1”). That is, the non-volatile memory system 100 may allocate a weight of strong 1 to the data (bit) that is read from the memory cell having a threshold voltage included in the period {circle around (1)} in which the reliability data RDTA is identified as “11”. The non-volatile memory system 100 may set data (bit), which is read from the memory cell having a threshold voltage included in the period {circle around (2)} in which the reliability data RDTA is identified as “10”, as weak 1 (which represents that there is a low probability that a relevant data (bit) value will be identified as “1” and will be “1”). That is, the non-volatile memory system 100 may allocate a weight of weak 1 to the data (bit) that is read from the memory cell having a threshold voltage included in the period {circle around (2)} in which the reliability data RDTA is identified as “10”.
Likewise, the non-volatile memory system 100 may allocate a weight of strong 0 (which represents that there is a high probability that a relevant data (bit) value will be identified as “0” and will be “0”) to data (bit) that is read from the memory cell having a threshold voltage included in the period {circle around (3)} in which the reliability data RDTA is identified as “00”, and may allocate a weight of weak 0 (which represents that there is a low probability that a relevant data (bit) value will be identified as “0” and will be “0”) to data (bit) that is read from the memory cell having a threshold voltage included in the period {circle around (4)} in which the reliability data RDTA is identified as “01”. The weight obtained by the soft decision operation may be used as an error correction reference.
Referring to
However, if the first read data is not correctable (S225=N), then the first block is set (or designated) as a first temporary bad block, and the read data stored in the first temporary bad block is then read using one or more soft read voltages (S240). Next, a determination is made as to whether an error has occurred in the second read data (S250) and whether the error in the second read data is correctable (S255). If the error in the second read data is correctable (S255=Y), the second read data is corrected (S260), else if the error in the second read data is not correctable (S255=N) the first block is set as a bad block (S270).
In this manner, acceptable first read data (S220=N), corrected first read data (S230), acceptable second read data (S250=N), and corrected second read data may be determined to be final read data (S280).
Therefore, the read method in the memory system according to an embodiment of the inventive concept may set the first block as the first temporary bad block in discrimination from a general bad block when the error that has occurred in the first read operation (e.g., hard decision) is not corrected, and use the first temporary bad block, thereby improving the operation of the memory device or the memory system.
For example, the read method in the memory system according to an embodiment of the inventive concept may set the first temporary bad block and a general bad block discriminatively, and perform the second read operation without detecting and correcting an error in the first read operation when there is a read command about the first temporary bad block after the first temporary bad block is set, thereby improving the read speed thereof.
For example, the read method in the memory system according to an embodiment of the inventive concept may set the first temporary bad block and a general bad block discriminatively, and may not store data in the first temporary bad block when data is not stored in a predetermined region or more in the normal blocks in the non-volatile memory cell array, thereby improving the reliability of read data.
For example, when data is not stored in about 90% or more of the memory cells included in the normal block, data may not be written/read into/from the first temporary bad block. In another example, when data is not stored in about 95% or more of the memory cells included in the normal block, data may not be written/read into/from the first temporary bad block.
Referring to
The memory controller Mctrl may include a read unit 210, a first determination unit 230, and a second determination unit 250. The read unit 210 generates a read command RCMD to read data from the memory cell array 220. One possible read operation will be described hereafter.
The read unit 210 may be used to generate a first read command [e.g., RCMD(V1, PAG1)] directed to read data is stored in the first page PAG1 of the first block BLK1. The resulting first read operation performed according to a first read scheme uses a hard read voltage V1 to make a hard decision. The first determination unit 230 may receive the resulting first read data (R_DATA1) corresponding to the first read command. Then, the first determination unit 230 may determine whether an error has occurred in the first read data and whether the error is correctable to generate a determination result [e.g., DET(R_DATA1)].
When there is an error in the first read data (R_DATA1) and the error is not correctable, the read unit 210 may be used to generate a control command [e.g., MRK(BLK1, LEV1)] to set the first block BLK1 as a first temporary bad block (Bad Block_lev1), and to generate a second read command [e.g., RCMD(V21, V22, PAW)] to re-read the first page PAG1 according to a second read scheme that uses a plurality of soft read voltages V21 and V22.
The second determination unit 250 may then receive the resulting second read data (e.g., R_DATA21, and R_DATA22) corresponding to the second read command in order to generate final read data (R_OUT).
Therefore, when an error in the first read data is not corrected in response to a hard decision command, the non-volatile memory system 200 may generate a control command to designate the first block BLK1 as the first temporary bad block, and thereby improve the operating speed of the memory device or the memory system by using the designation of the first temporary bad block.
For example, the non-volatile memory system 200 may set the first temporary bad block and a general bad block discriminatively, and perform the second read operation without detecting and correcting an error in the first read operation when there is a read command about the first temporary bad block after the first temporary bad block is set, thereby improving the read speed thereof.
Alternately and analogously to the description given above, the non-volatile memory system 200 may also set the first temporary bad block and a general bad block discriminatively, and may not store data in the first temporary bad block when data is not stored in a predetermined region or more in the normal blocks in the non-volatile memory cell array, thereby improving the reliability of read data.
Referring to
Referring to
The non-volatile memory device include one or more memory cell arrays 320, each including at least a first memory block (BLK1) and a second memory block (BLK2).
The read unit 310 of the memory controller will receive second read data (e.g., R_DATA21 and R_DATA22) in response to a second read command [e.g., RCMD(V21, V22, PAG0] and generates final read data (R_OUT). However, the memory controller thereafter stores the corrected second read data the second (known good) block BLK2 using a write command [e.g., WCMD (BLK1, BLK2)].
The non-volatile memory system 400 of
Unlike the non-volatile memory device MEM of
That is, the read unit 410 may be used to generate a read command READ(V1) to read data stored in the first page PAG1 of the first block BLK1 using a hard read voltage V1 according to a hard decision scheme. The on-chip controller 440 may also be used to receive first read data (R_DATA1) corresponding to the first read command READ(V1), to determine whether an error has occurred in the hard decision, and to generate a determination result DET(R_DATA1).
When there is an error in the first read data (R_DATA1), the read unit 410 may be used to generate a control command (e.g., MRK(BLK1, LEV1)] to set the first block as a first temporary bad block, and to generate a second read command [e.g., READ(V21, V22)] to re-read the first page using a plurality of soft read voltages V21 and V22 according to a second read scheme.
The on-chip controller 440 then receives second read data (R_DATA21, R_DATA22) corresponding to the second read command and generates final read data (R_OUT). Therefore, the non-volatile memory system 400 may perform a read command by use of the on-chip controller 440.
The computing system CSYS includes a processor CPU, a user interface UI, and a memory system MSYS that are electrically connected to a bus BUS. The memory system MSYS includes a memory controller Ctrl and a non-volatile memory device MEM. N-bit data (N is an integer equal to or greater than 1), which is or will be processed by the processor CPU, may be stored in the non-volatile memory device MEM through the memory controller Ctrl. The memory system MSYS of
The computing system CSYS may further include a power supply device PS. Also, when the non-volatile memory device MEM is a flash memory device that performs a program operation by the program method of
When the computing system CSYS is a mobile device, the computing system CSYS may further include a battery for supplying an operation voltage of the computing system CSYS, and a modem such as a baseband chipset. Also, it will be apparent to those or ordinary skill in the art will that the computing system CSYS may further include an application chipset, a camera image processor (CIS), and a mobile dynamic random-access memory (DRAM), and thus a detailed description thereof will be omitted herein.
Referring to
Also, the memory card MCRD may be implemented by a compact flash card (CFC), a microdrive, a smart media card (SMC), a multimedia card (MMC), a security digital card (SDC), a memory stick, or a USB flash memory driver. Therefore, according to the memory card MCRD of
Referring to
A host interface HOST I/F receives and transmits a request of the host to the processor PROS, or receives and transmits data of the non-volatile memory device MEM to the host. The host interface HOST I/F may interface with the host through various interface protocols, such as Universal Serial Bus (USB), Man Machine Communication (MMC), Peripheral Component Interconnect-Express (PCI-E), Serial Advanced Technology Attachment (SATA), Parallel Advanced Technology Attachment (PATA), Small Computer System Interface (SCSI), Enhanced Small Device Interface (ESDI), and Intelligent Drive Electronics (IDE). Data, which will be transmitted to or is transmitted from the non-volatile memory device MEM, may be temporarily stored in the cache buffer CBUF. The cache buffer CBUF may be a static random-access memory (SRAM).
The solid state drive SSD may be implemented by the non-volatile memory system 100 of
Referring to
While this inventive concept has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood that various changes in form and details may be made therein without departing from the scope of the inventive concept as defined by the following claims.
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